Multiple fluid pathway energy converter

Abstract

 An axial flow fan combining a shroud (12) defining a fluid pathway (34) coaxial with the shroud (12), a motor (30) having a rotatable shaft (28) mounted within the fluid pathway (34) coaxial with the shroud (12), an impeller (14) mounted to the shaft (28) with the impeller (14) having a hub (16) having a face (20) across the fluid pathway (34) and having an edge (24) at the radial perimeter of the hub (16) and having a plurality of blades (18) mounted radially to the edge (24) of the hub (16) and a set of guide vanes (32) disposed axially with respect to the impeller (14) and mounted within the fluid pathway (34). The hub (16) has at least one face orifice (22) in the face (20) of the hub (16) communicating with at least one edge orifice (26) in the edge (24) of the hub (16) allowing fluid to flow through the hub, providing both axial fluid flow (36) and hub fluid flow (38) through the fan.

Description

Technical Field

[0001] The present invention relates generally to axial flow impellers and more particularly to axial flow energy converters (e.g. fans) utilizing certain impellers.

Background Art

[0002] Axial flow devices, particularly fans, are well-known in the art. One reference text in this art is William C. Osborne, Fans, 2nd Edition (in SI/metric units), 1977, published by Pergamon Press, Inc., Maxwell House, Fairview Park, Elmsford, New York 10523. Particular reference may be made to chapter 2 which describes differing types of fans.

[0003] One application of an axial flow fan is in a fluid pumping device incorporated within a clean air hat which pumps air through a filter to a human wearer. In order to provide sufficient purified air to a wearer working in the environment where the hat is being worn, a certain minimum volumetric flow rate of air must be drawn into the hat. To enable the hat to be completely portable, it is desirable that the pumping device (fan) be battery powered. For a hat using batteries, it is preferred that the hat be as light as possible and that it be able to operate as long as possible. An axial flow fan which develops sufficient differential pressure and volumetric flow rate and minimizes battery drain (power consumption) is desirable.

[0004] In one axial flow fan designed for a clean air hat marketed under the tradename "Airhat" by Minnesota Mining and Manufacturing Company, a small electric motor is mounted within a shroud with a set of guide vanes. An impeller is attached to the motor shaft and has a central hub and a plurality of blades radially mounted to the edge of the hub with each of the blades set at an attack angle in order to pump fluid (air) through the fan. This axial flow fan exhibits certain performance characteristics of pressure differential and volumetric flow at a certain voltage and amperage (power consumption).

[0005] There is desired an axial flow fan which develops improved pressure and volumetric flow and minimizes battery drain (power consumption).

Disclosure of Invention

[0006] An axial flow fan is provided having a tubular shroud defining a fluid pathway coaxial within the shroud and a motor having a rotatable drive shaft mounted within the fluid pathway coaxial with the shroud. A hub is mounted to the shaft of the motor with the hub having a face across the fluid pathway and having an edge at the radial perimeter of the hub. A plurality of blades are mounted radially to the hub, each of the plurality of blades set with an attack angle with respect to the fluid pathway. A set of guide vanes is disposed axially with respect to the plurality of blades and mounted within the fluid pathway. The hub has at least one face orifice in the face of the hub communicating with at least one edge orifice in the edge of the hub allowing fluid flow through the hub. In preferred embodiments, the tubular shroud is cylindrical in cross section and the plurality of blades are mounted to the edge of the hub. In a still preferred embodiment, the hub has no radial partitions under the face of the hub and between a shaft mounting portion and the edge of the hub. In preferred embodiments the axial flow fan has a plurality of face orifices in the face of the hub communicating with a plurality of edge orifices in the edge of the hub allowing a plurality of fluid pathways through the hub. In a preferred embodiment, the cumulative cross-sectional area of the plurality of edge orifices is at least as great as the cumulative cross sectional area of the plurality of face orifices. In a preferred embodiment, the number of the plurality of edge orifices equals the number of the plurality of blades.

[0007] The present invention also provides an axial fluid flow energy converter. The converter has a tubular shroud defining a fluid pathway coaxial with the shroud. A rotational energy converter (e.g. a generator) is mounted within the fluid pathway coaxial with the shroud. The rotational energy converter has a rotatable shaft. An impeller is mounted to the shaft. The impeller has a hub having a face across the fluid pathway, and has an edge at the radial perimeter of the hub. The impeller also has a plurality of blades mounted radially to the edge of the hub. Each of the plurality of blades is set with an attack angle with respect to the fluid pathway. The hub has at least one face orifice in the face of the hub communicating with at least one edge orifice in the edge of the hub allowing fluid to flow through the hub. The axial fluid flow energy converter also has a set of guide vanes disposed axially with respect to the impeller and mounted within the fluid pathway.

[0008] The additional fluid pathway(s), in conjunction with the blades, guide vanes, and shroud provide significant operating advantages over conventional design. It has been shown that the axial flow fan device of the present invention increases either or both the pressure pumping capability and the volumetric flow while at the same time, reduces the electrical energy consumption of the electric motor. It is believed that the interaction of the axial pumping of the blades combined with the pumping of air resulting from the additional fluid pathway(s) through the hub results in these significant and unexpected desirable operating characteristics.

Brief Description of Drawings

[0009] The foregoing advantages, construction and operation of the present invention will become more readily apparent from the following description and accompanying drawings in which:

FIGURE 1 is an isometric view of the complete axial flow device of the present invention;

FIGURE 2 is an end view of the axial flow device of the present invention;

FIGURE 3 is a sectional view of the axial flow device of Figure 2 illustrating the multiple fluid pathways;

FIGURE 4 illustrates in diagrammetric form a test set up used to determine the operative effects of the present invention;

FIGURE 5 is a prior art impeller;

FIGURE 6 is an impeller modified to form the multiple fluid pathways of the present invention;

FIGURE 7 is an alternative impeller according to the present invention with internal hub ribs;

FIGURE 8 is a bottom view of the impeller of Figure 7;

FIGURE 9 is an alternative impeller according to the present invention with notches forming edge orifices;

FIGURE 10 is an alternative impeller according to the present invention; and

FIGURE 11 is an alternative impeller according to the present invention with slots for face orifices.

Detailed Description

[0010] Figures 1 and 2 illustrate the complete axial fluid flow energy converter or axial flow fan 10 of the present invention. A tubular shroud 12 defines the fluid pathway in which an impeller 14 is mounted. The impeller 14 has a hub 16 with a plurality of blades 18 radially mounted on the edge of the hub 16. The face 20 of the hub 16, across the fluid pathway 34, has a plurality of face orifices 22 through which fluid may enter, or exit depending upon the design of the device. In the preferred embodiment of Figure 1 a plurality of face orifices 22 are illustrated. It is to be understoud, of course, that it is considered within the scope of the present invention that a single face orifice 22 could be utilized to obtain the multiple fluid pathways of the present invention. The edge 24 of the hub 16 to which the blades 18 are mounted also contain a plurality of edge orifices 26. Edge orifices 26 communicate with face orifices 22 to form an exit, or an entrance depending upon device design, for the multiple fluid pathway through the hub 16. While the preferred embodiment illustrated in Figures 1 and 2 show a plurality of edge orifices 26, it is to be understood that it is within the scope of the invention that a single edge orifice 26 could be utilized to obtain the multiple fluid pathways of the present invention. Disposed axially with respect to the impeller 14 is a set of guide vanes 32 which are utilized in a conventional manner. In the preferred embodiment illustrated in Figures 1 and 2, the guide vanes 32 are disposed aft the impeller 14 with respect to the fluid flow. However, in other embodiments the guide vanes 32 may be disposed on either or both sides of the impeller 14.

[0011] Figure 3 illustrates a cross section of the device 10 of Figure 2 taken along Section Line 3-3. Again a tubular shroud 12, which preferably is cylindrical, defines a fluid pathway 34. The impeller 14 is mounted axially in the fluid pathway 34 and has a hub portion 16 and a plurality of blades 18. The blades 18 are set at an attack angle with respect to the fluid in order to pump that fluid, e.g. air. The face 20 of the hub 16 across the fluid pathway 34 contains face orifices 22. The edge 24 of the hub 16 contain edge orifices 26. Guide vanes 32 are disposed axially with respect to the impeller 14 also within the fluid pathway 34. The impeller 14 is mounted on the drive shaft 28 of motor 30.

[0012] Conventional axial fluid flow 36 is illustrated in Figure 3 entering the fluid pathway 34 at the top of the tubular shroud 12. This axial fluid flow 36 is produced conventionally by the blades 18 in conjunction with guide vanes 32. Figure 3 also illustrates the multiple fluid pathways created by the face orifices 22 and edge orifices 26. A hub fluid flow 38, not present in conventional axial flow fan design, is created by face orifices 22 and edge orifices 26. In operation, hub fluid flow 38 is formed when the fluid passes through face orifice 22, through the interior 40 of hub 16, exiting through edge orifice 26 acting in conjunction with blade 18 and guide vane 32 and continuing through the fluid pathway 34. This hub fluid flow 38 is not present in conventional impeller 14 and axial flow device 10 design. It is the hub fluid flow 38 in conjunction with conventional axial fluid flow 36 which produces the striking operating characteristics of the device of the present invention.

[0013] The test arrangement illustrated in Figure 4 allows the measurement of the volume of air through the device 10 under a variety of pressure loadings and at a variety of impeller 14 speed conditions. A subject axial flow device 10 is mounted with respect to an exhaust chamber 44. An auxiliary blower 42 can be used to create a range of static pressure conditions in the exhaust chamber 44. A flow meter 46 can measure the volume of air flowing through the device 10. A static pressure tap 48 coupled to a manometer 50 allows the exhaust chamber 44 pressure to be monitored. The static pressure tap 48 is referenced against ambient atmosphere whose pressure is the device 10 inlet pressure. Thus the static pressure tap measures the pressure load across the device 10. The device 10 is coupled to a power source with leads 52 whose power consumption is monitored by volt meter 54 and ammeter 56. The speed of the impeller 14 of the device 10 is monitored by a Strobotac 58. In a preferred embodiment the following equipment is utilized:

[0014] The fluid stream energy in watts may be found by first determining the product of the actual pounds of fluid (e.g. air) flowing through the device 10 per second, times the pressure differential across the device 10 expressed in feet of fluid at the flowing condition and dividing this product by 550 to determine the fluid horsepower, and finally by multiplying the result by 745.7 to obtain watts. The energy in watts supplied to the motor 30 is the product of the motor voltage and motor amperage using volt meter 54 and ammeter 56. Combining such operations yields the following equation:

[0015] Device Efficiency

where F equals the flow rate in cubic feet per minute, P equals the pressure gain in inches of water, V equals the voltage of the volt meter 54 in volts, and A equals the current of ammeter 56 in amperes. The actual atmospheric conditions for a given test are used to correct the measured readings to actual flow in cubic feet per minute. The correction is accomplished by the use of the following equation:

Actual Flow = Indicated Flow (ICFM)

where Pa equals atmospheric pressure in pounds per square inch ambient and Ta equals atmospheric temperature in degrees Rankine.

[0016] The test set up in Figure 4 was used by setting the device 10 voltage and the auxiliary blower 42 flow until the pressure gain across the device was 0.0 (free air condition). The impeller 14 speed, the voltage, the amperage, and the indicated air flow were then recorded. The pressure gain across the fan was then adjusted by varying anxiliary blower 42 in a stepwise manner and all readings were again repeated until the auxiliary blower 42 was no longer energized, at which point the device was under maximum test pressure and minimum test flow.

[0017] Figure 5 illustrates a prior art impeller 14. The prior art impeller 14 has a hub 16 and a plurality of blades 18 radially affixed to the edge 24 of the hub 16. The hub 16 has a face 20 across the fluid flow which prevents fluid passage through the hub 16.

[0018] The multiple fluid pathway impeller 14 of the; present invention is more readily illustrated with Figure 6. Again, impeller 14 has a hub 16 and a plurality of blades radially affixed to the edge 24 of the hub 16. The face 20 of the hub 16 across the fluid pathway contains face orifices 22, or at least one, and the edge 24 of the hub 16 contain edge orifices 26, or at least one. The interior 40 of the hub 16 allows fluid passing through face orifices 22 to communicate with edge orifices 26. The use of the face orifices 22 in conjunction with the edge orifices 26 creates the multiple fluid pathways which result in the favorable operation of the present invention.

[0019] The striking results of the impeller 14 of the present invention can be illustrated by a test utilizing the test set up of Figure 4. In this test the prior art impeller 14 of Figure 5 was compared with the impeller 14 of the present invention illustrated in Figure 6. The test was conducted with a motor 30 voltage of 5.2 volts in a room temperature of 80° Fahrenheit (23° Centigrade) with a barometric pressure of 736 Torr. The fluid flow, pressure differential, current draw, impeller speed and efficiency of the device utilizing the selected impeller are illustrated in Table 1.

[0020] As can he seen in Table 1, the fluid flow under "free air" conditions of 0.0 inches water pressure load is approximately equal for the prior art impeller 14 of Figure 5 as for the impeller 14 of the present invention of Figure 6. However, as the pressure load increases the multiple fluid pathway impeller of Figure 6 provides significantly more flow. At 0.70 inches of water the flow increase is approximately 38%. At this point the current drain is reduced and the impeller speed is greater. Therefore, significantly more fluid (air) is being delivered with lower power consumption. The result is that the user of the device 10 of the present invention, when coupled to a powered respirator or other device, will experience additional air flow and longer battery life. The efficiency of the impeller 14 of Figure 6 is above the efficiency for the impeller of Figure 5 by as much as 49% (at 0.65 inches of water).

[0021] The import of axial fluid flow 38 in obtaining the improved performance of the device of the present invention can be further illustrated with another test performed with the test arrangement of Figure 4. In this test the impeller 14 of Figure 6 was utilized. The use of this impeller 14 in the multiple fluid pathway environment was compared with a similar environment in which the axial fluid flow 38 through the edge orifices 26 blocked with a cylindrical ridge (not shown) affixed the motor 30 housing. The test was conducted with a motor 30 voltage of 5.2 volts in a room temperature of 74° Fahrenheit (21° Centrigrade) with a barometric pressure of 732 Torr (with the cylindrical ridge) and 740 Torr (without the cylindrical ridge). The fluid flow, pressure differential, current draw, impeller speed and efficiency are illustrated in Table 2.

[0022] As can be seen from Table 2, the effect of the removal of the cylindrical ridge is evident above pressures of 0.70 inches of water by increased fluid flow, significantly greater efficiency, and lower current drain.

[0023] The impeller 14 illustrated in Figures 7 and 8 is similar to the impeller 14 of Figure 6. Both impellers 14 have a hub 16 to which are radially attached blades 18. Both have face orifices 22 in the face 20 of the hub 16 and edge orifices 26 on the edge 24 of hub 16. However, where the hub 16 of impeller 14 of Figure 6 is open allowing free communication between face orifices 22 and edge orifices 26, impeller 14 of Figures 7 and 8 feature internal hub ribs 60 extending radially between the portion of the hub 16 supporting the drive shaft 28 and the edge 24. The effect of the ribs 60 is to limit fluid passage from one face orifice 22 to a single edge orifice 26. Note that multiple fluid pathways are still available through the hub 16 of the impeller 14 of Figures 7 and 8.

[0024] The operation of an impeller 14 as described in Figures 7 and 8 was tested with an impeller 14 similar to, although not identical to, the impeller described in Figure 6. The test voltage was 5.2 volts, the room temperature was 75° Fahrenheit, (22° Centigrade) and the barometric pressure was 734 Torr. The results of this experiment are shown in Table 3.

[0025] Table 3 shows that while the overall effect of the hub ribs 60 is negative when compared to an impeller 14 of the type of Figure 6, that the impeller 14 illustrated in Figures 7 and 8 still operates substantially better than the prior art impeller 14 of Figure 5. The impeller 14 of Figures 7 and 8 requires somewhat more current at all conditions and the fluid flow and the impeller speed are both slightly reduced at pressures above 0.30 inches of water. These effects combine to reduce the efficiency over all ranges of operation slightly as compared to the impeller 14 similar to that described in Figure 6. The benefit, however, of the ribs 60 is to add hub strength.

[0026] The impellers 14 illustrated in Figures 9 and 10 are similar to the impellers 14 illustrated in Figure 6. Figures 9 and 10 illustrate, however, that the edge orifices 26 need not be circular passageways through the edge 24 of the hub 16. In Figures 9 and 10 the impellers 14 have edge orifices constructed of notches in the edge 24 creating a somewhat different fluid passageway. The impellers 14 of Figures 9 and 10, however, operate substantially fundamentally as advantageously as the impeller 14 illustrated in Figure 6. Results of tests utilizing impellers 14 as illustrated in Figures 9 and 10 are summarized in Table 4. The test voltage was 5.2 volts, the room temperature was 75° Fahrenheit, (22° Centigrade) and the barometric pressure was 740 Torr.

[0027] It can be seen in Table 4 that the impellers 14 illustrated in Figures 9 and 10 both have the improved operating characteristics of the multiple fluid pathway impellers of the present invention. The impeller 14 of Figure 9 has seven face orifices 22, each with a diameter of 0.10 inches. This compares with the impeller 14 of Figure 10 which has six face orifices 22, each of 0.187 inch diameter. It will be noted that the performance of the impellers 14 of Figures 9 and 10 are nearly equal. A slight gain in efficiency is seen for the impeller 14 of Figure 10.

[0028] The impellers 14 of Figure 9 and Figure 10 illustrate that the multiple fluid pathways of the invention can be allowed by edge orifices 26 of differing shapes and configurations. In addition, the edge orifices 26 may be formed from the clearance between the portion of the edge 24 of the impeller 14 closest the motor 30 and the motor 30 housing. The clearance between the edge 24 of the impeller 14 and the motor 30 allows fluid to enter face orifices 22, pass through the impeller 14 and exit onto the guide vanes 32 at or near the blades 18 to form the multiple fluid pathway. The result was confirmed in the test set-up of Figure 4 in which impellers 14 were compared. The first (small) impeller 14 had a small gap (clearance) of 0.053 inches between the edge 24 and the face of the motor 30 housing. The second (large) impeller 14 had a larger gap (clearance) of 0.093 inches between the edge 24 and the face of the motor 30 housing. The blade 18 to guide vane 32 clearance was held constant. No other edge orifices 26 were used other than the edge 24 clearance. The test voltage was 5.2 volts, the room temperature was 76° Fahrenheit (22.5° Centigrade) and the barometric pressure was 739 Torr. The fluid flow, pressure differential, current draw, impeller speed and efficiency are illustrated in Table 5.

[0029] As Table 5 illustrates, the impeller 14 with the larger clearance demonstrated an increasing fluid flow while reducing current drain. The efficiency improves as well.

[0030] The impeller 14 illustrated in Figure 11 shows an alternative geometry for face orifices 22 in the face 20 of hub 16. Figure 11 illustrates that the face orifices 22 need only admit fluid through the face 20 of the hub 16 for communication to edge orifices 26. The particular cross-sectional shape of face orifices 22 is not critical.

[0031] Thus, it can be seen that there has been shown and described a novel axial flow device. It is to be understood, however, that various changes, modifications, and substitutions in the form of the details of the described device can be made by those skilled in the art without departing from the scope of the invention as defined by the following claims.

Claims

1. An axial flow fan (10), comprising:

a tubular shroud (12) defining a fluid pathway (34) coaxial within said shroud (12); a motor (30) mounted within said fluid pathway (34) coaxial with said shroud (12), said motor (30) having a rotatable drive shaft (28);

a hub (16) mounted to said shaft (28) of said motor (30), said hub (16) having a face (20) across said fluid pathway (34) and having an edge (24) at the radial perimeter of said hub (16);

a plurality of blades (18) mounted radially to said hub (16), each of said plurality of blades (18) set with an attack angle with respect to said fluid pathway (34); and

a set of guide vanes (32) disposed axially with respect to said plurality of blades (18) and mounted within said fluid pathway (34);

said hub (16) having at least one face orifice (22) in said face (20) of said hub (16) communicating with at least one edge orifice (26) in said edge (24) of said hub (16) allowing fluid flow (38) through said hub (16).

2. An axial flow fan (10) as in claim 1 wherein said shroud (12) is cylindrical in cross-section.

3. An axial flow fan (10) as in claim 2 wherein said plurality of blades (18) are mounted to said edge (24) of said hub (16).

4. An axial flow fan (10) as in claim 3 wherein said hub (16) has no radial partitions (60) under said face (20) of said hub (16) and between a shaft mounting portion and said edge (24) of said hub (16).

5. An axial flow fan (10) as in claim 3 wherein said hub (16) has a plurality of face orifices (22) in said face (20) of said hub (16) communicating with a plurality of edge orifices (26) in said edge (24) of said hub (16) allowing a plurality of fluid pathways (35) through said hub (16).

6. An axial flow fan (10) as in claim 5 wherein the number of said plurality of edge orifices (26) equals the number of said plurality of blades (18).

7. An axial flow fan (10) as in claim 5 wherein the cumulative cross-sectional area of said plurality of edge orifices (26) is at least as great as the cumulative cross-sectional area of said plurality of face orifices (22).

8. An axial flow fan (10) as in claim 5 wherein said plurality of face orifices (22) are circular in cross-section.

9. An axial flow fan (10) as in claim 8 wherein said plurality of edge orifices (26) are circular in cross-section.

10. An axial flow fan (10) as in claim 8 wherein said plurality of edge orifices (26) are formed by a notch in said edge (24) of said hub (16).

Drawing